Abstract
We have previously shown that mutant B lymphoblastoid cell lines, totally deficient in expression of human leucocyte antigen (HLA)-class II molecules, but with normal HLA-class I expression, develop enhanced susceptibility to natural killer (NK) and lymphokine-activated killer (LAK) cell lysis. The current investigations were aimed at examining the role of HLA-DR and native peptides occupying the antigen-presenting grooves of HLA-class II molecules in protecting mutants of the same B-lymphoid lines against LAK-mediated lysis. No augmentation in LAK lysis was observed despite using two mutant B-cell lines (9.22.3 and 3.1.0) that lacked HLA-DR. Both these lines expressed HLA-DP and HLA-DQ. However, when using other B-cell lines with point mutations in certain regions of the HLA-DR alpha-chain (78, 80 and 96) significantly increased their susceptibility to LAK lysis despite normal expression of HLA-DR and the other class I and II molecules. Of particular interest was the finding that absence of native peptides in antigen-presenting grooves of all the HLA-class II molecules did not render the mutant B cell (9.5.3) susceptible to LAK lysis. These observations support the concept that there are different NK or LAK clones. Certain LAK clones recognize 'self' major histocompatibility complex (MHC) antigens (but not the native peptides in their antigen-presenting grooves). Presence of 'self' MHC antigens inhibits such clones. Conversely, other NK or LAK clones recognize 'non-self' in the context of MHC antigens. Hence, point mutations at certain specific sites on the MHC molecules or foreign peptides in the antigen-presenting grooves enhances the susceptibility of these cells to LAK clones recognizing 'non-self'.